HSMx-A2-xx-xxxxx Bi-Color HSMx-A3xx-xxxxx Tri-Color

Data Sheet HSMx-A3xx-xxxxx Tri-Color Description This family of SMT LEDs is packaged in the industry standard PLCC-4 package. These SMT LEDs have high reliability performance and are designed to work under a wide range of environmental conditions. This high reliability feature makes them ideally suited to be used under harsh interior automotive as well as interior signs application conditions. To facilitate easy pick and place assembly, the LEDs are packed in EIA-compliant tape and reel. Every reel is shipped in single intensity and color bin, except red color to provide close uniformity. These LEDs are compatible with IR and TTW solder reflow process. This super wide viewing angle at 120 together with the built in reflector pushing up the intensity of the light output makes these LED suitable to be used in the interior electronics signs. The flat top emitting surface makes it easy for these LEDs to mate with light pipes. This is suitable for general backlighting in automotive interior, office equipment, industrial equipment, and home appliances. Features Industry Standard PLCC-4 package (Plastic Leaded Chip Carrier) High reliability LED package due to enhanced silicone resin material High brightness using AlInGaP and InGaN dice technologies Available in full selection of colors Super wide viewing angle at 120 Available in 8 mm carrier tape on 7-inch reel Compatible with IR soldering process Applications Electronic signs and signals Interior full color sign Variable message sign Interior automotive Instrument cluster backlighting Central console backlighting Cabin backlighting Office automation, home appliances, industrial equipment Front panel backlighting Display backlighting CAUTION! HSMF-Axxx-xxxxx LEDs are Class 2 ESD sensitive. Please observe appropriate precautions during handling and processing. Refer to Avago Application Note AN-1142 for additional details. March 11, 2019

Package Drawing 2.8 ± 0.2 1.9 ± 0.2 2.2 ± 0.2 (2) (3) 0.1 TYP. 0.8 ± 0.1 3.2 ± 0.2 3.5 ± 0.2 0.8 ± 0.3 CATHODE MARKING (1) (4) 0.7 ± 0.1 0.5 ± 0.1 All dimensions in millimeters (mm). Tri Color 1 Cathode (Color 1) 2 Common Anode 3 Cathode (Color 3) 4 Cathode (Color 2) Bi Color 1 Cathode (Color 1) 2 Anode (Color 1) 3 Cathode (Color 2) 4 Anode (Color 2) 2

Device Selection Guide Bi Color Part Number Color 1 Color 2 HSMF-A201-xxxxx GaP Red GaP Yellow Green HSMF-A202-xxxxx GaP Red GaP Yellow HSMF-A203-xxxxx GaP Red GaP Emerald Green HSMF-A204-xxxxx GaP Orange GaP Yellow Green HSMF-A205-xxxxx GaP Orange GaP Emerald Green HSMF-A206-xxxxx GaP Yellow GaP Yellow Green HSMF-A211-xxxxx AlGaAs Red GaP Yellow Green HSMF-A212-xxxxx AlGaAs Red GaP Yellow HSMF-A222-xxxxx AlInGaP Red AlInGaP Amber HSMF-A226-xxxxx AlInGaP Amber AlInGaP Yellow Green Color 1 Color 2 Min. I V at 20 ma Typical I V at 20 ma Min. I V at 20 ma Typical I V at 20 ma Part Number Bin ID (mcd) (mcd) Bin ID (mcd) (mcd) HSMF-A201-A00J1 K2 9.0 16.0 L1 11.2 20.0 HSMF-A202-A00J1 K2 9.0 16.0 K1 7.2 12.0 HSMF-A203-A00J1 K2 9.0 16.0 J1 4.5 8.0 HSMF-A204-A00J1 K2 9.0 16.0 L1 11.2 20.0 HSMF-A205-A00J1 K2 9.0 16.0 J1 4.5 8.0 HSMF-A206-A00J1 K2 9.0 16.0 L1 11.2 20.0 HSMF-A211-A00J1 L2 14.0 25.0 L1 11.2 20.0 HSMF-A212-A00J1 L2 14.0 25.0 K1 7.2 12.0 HSMF-A222-A00J1 P1 45.0 80.0 P1 45.0 80.0 HSMF-A226-A00J1 P2 56.0 100.0 M2 22.4 60.0 The luminous intensity I V, is measured at the mechanical axis of the lamp package. The actual peak of the spatial radiation pattern may not be aligned with this axis. I V tolerance = ±10%. 3

Tri Color Part Number Color 1 Color 2 Color 3 HSMF-A341-xxxxx AllnGaP Red InGaN Green InGaN Blue Color 1 Color 2 Color 3 Min. Iv @ 20 ma Typical Iv @ 20 ma Min. Iv @ 20 ma Typical Iv @ 20 ma Min. Iv @ 20 ma Typical Iv @ 20 ma Part Number HSMF-A341-A00J1 Part Numbering System Bin ID (mcd) (mcd) Bin ID (mcd) (mcd) Bin ID (mcd) (mcd) K2 9.0 13.0 L2 14.0 20.0 K2 9.2 10.0 P1 45.0 80.0 R1 112.5 160.0 K2 9.2 10.0 P1 45.0 80.0 R1 112.5 160.0 K2 9.2 10.0 P1 45.0 80.0 R1 112.5 160.0 N1 28.5 40.0 P1 45.0 80.0 R1 112.5 160.0 N1 28.5 40.0 The luminous intensity I V, is measured at the mechanical axis of the lamp package. The actual peak of the spatial radiation pattern may not be aligned with this axis. I V tolerance = ±10%. HSM X1 A X2 X3X4 X5X6 X7 X8X9 Packaging Option Color Bin Selection Intensity Bin Limit Device Specification Configuration Package Type LED Chip Color 4

Absolute Maximum Ratings (T A = 25 C) AlInGaP Parameters GaP AlGaAs Red, Amber Yellow Green GaN/InGaN DC Forward Current a 30 ma 30 ma 30 ma b,c 20 ma c 20 ma Peak Forward Current d 100 ma 100 ma 100 ma 100 ma 100 ma Power Dissipation 78 mw 78 mw 72 mw 48 mw 120 mw Reverse Voltage 5V Junction Temperature 110 C Operating Temperature 55 C to +100 C Storage Temperature 55 C to +100 C a. Derate linearly as shown in figure 4. b. Drive Current between 10 ma and 30 ma are recommended for best long-term performance. c. Operation at current below 5 ma is not recommended. d. Duty factor = 10%, Frequency = 1 khz. Optical Characteristics (T A = 25 C) Dominant Luminous Intensity/ Peak Wavelength Wavelength Viewing Angle Luminous Efficacy η v Total Flux Color λ PEAK (nm) Typ. λ D (nm) a Typ. 2θ 1/2 (Degrees) b Typ. (lm/w) c Typ. I v (mcd)/ɸ v (mlm) Typ. GaP Red 635 626 120 120 0.45 AlGaAs Red 645 637 120 63 0.45 AlInGaP Red 635 626 120 150 0.45 AlInGaP Red Orange 621 615 120 240 0.45 GaP Orange 600 602 120 380 0.45 AlInGaP Amber 592 590 120 480 0.45 GaP Yellow 583 585 120 580 0.45 AlInGaP Amber 592 590 120 480 0.45 GaP Yellow Green 565 569 120 590 0.45 GaP Emerald Green 558 560 120 650 0.45 InGaN Green 523 525 120 500 0.45 InGaN Blue 468 470 120 75 0.45 GaN Blue 428 462 120 65 0.45 AlInGaP Yellow Green 575 571 120 620 0.45 a. The dominant wavelength, λ D, is derived from the CIE Chromaticity Diagram and represents the color of the device. b. θ 1/2 is the off-axis angle where the luminous intensity is 1/2 the peak intensity. c. Radiant intensity, I e in watts/steradian, may be calculated from the equation I e = I v /η v, where I v is the luminous intensity in candelas and η v is the luminous efficacy in lumens/watt. 5

Electrical Characteristics (T A = 25 C) Forward Voltage V F (Volts) @ I F = 20 ma Reverse Voltage V R @ 100 µa Reverse Voltage V R @ 10 µa Dice Technology Typ. Max. Min. Min. GaP 2.2 2.6 5 AS AlGaAs 1.9 2.6 5 AlInGaP 1.9 2.4 5 GaN Blue 3.9 4.3 5 InGaN 3.4 4.05 5 Figure 1: Relative Intensity vs. Wavelength RELATIVE INTENSITY 1.0 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 BLUE CYAN GREEN YELLOW GREEN AMBER ORANGE RED ORANGE RED 0.1 RELATIVE INTENSITY 0 380 430 480 530 580 630 680 730 780 1.0 0.8 0.6 0.4 0.2 GaP EMERALD GREEN GaP YELLOW GREEN GaN BLUE WAVELENGTH nm GaP YELLOW GaP ORANGE GaP RED 0 380 430 480 530 580 630 680 730 780 WAVELENGTH nm 6

Figure 2: Forward Current vs. Forward Voltage 35 FORWARD CURRENT ma 30 25 20 15 10 5 GaP AlGaAs AS AlInGaP InGaN GaN BLUE 0 0 1 2 3 4 FORWARD VOLTAGE V 5 Figure 3: Relative Intensity vs. Forward Voltage 1.8 RELATIVE LUMINOUS INTENSITY (NORMALIZED AT 20 ma) 1.6 Gap 1.4 AlInGaP AlGaAs 1.2 InGaN 1.0 GaN 0.8 0.6 0.4 0.2 0 0 5 10 15 20 25 30 35 DC FORWARD CURRENT ma Figure 4: Maximum Forward Current vs. Ambient Temperature. Derated based on T J MAX = 110 C, Rθ JA = 500 C/W (1 chip on). 35 CURRENT ma 30 25 20 15 10 GaP AS AlInGaP InGaN/GaN AlGaAs 5 0 0 20 40 60 80 100 120 TEMPERATURE C 7

Figure 5: Maximum Forward Current vs. Ambient Temperature. Derated based on T J MAX = 110 C, Rθ JA = 700 C/W (3 chip on). MAXIMUM FORWARD CURRENT ma 35 30 25 20 15 10 5 0 0 GaP AlGaAs AS AlInGaP InGaN/GaN 20 40 60 80 100 120 AMBIENT TEMPERATURE C Figure 6: Dominant Wavelength vs. Forward Current InGaN 540 DOMINANT WAVELENGTH nm 530 520 510 500 490 480 470 InGaN GREEN InGaN BLUE 460 0 5 10 15 20 25 30 CURRENT ma 35 8

Figure 7: Radiation Pattern 1.0 NORMALIZED INTENSITY 0.8 0.6 0.4 0.2 0-90 -80-70 -60-50 -40-30 -20-10 0 10 20 30 40 50 60 70 80 90 ANGULAR DISPLACEMENT DEGREES For detail information on reflow soldering of Avago surface mount LEDs, refer to Avago Application Note AN 1060 Surface Mounting SMT LED Indicator Components. 9

Figure 8: Recommended Soldering Pad Pattern 2.60 3.30 0.40 3.30 1.10 0.50 4.50 7.50 1.50 SOLDER RESIST Figure 9: Tape Leader and Trailer Dimension C A Figure 10: Tape Leader and Trailer Dimension 4 ± 0.1 4 ± 0.1 2 ± 0.05 2.29 ± 0.1 1.75 ± 0.1 +0.1 0 C 3.5 ± 0.05 8 +0.3 0.1 3.81 ± 0.1 A 3.05 ± 0.1 +0.1 0 8 0.229 ± 0.01 10

Figure 11: Reel Dimension 180 2 +0.5 0 Ø 20.5 ± 0.3 +0 62.5 2.5 Ø 13 ± 0.2 +1.50 8.4 (MEASURED AT OUTER EDGE) 0.00 LABEL AREA (111 mm x 57 mm) WITH DEPRESSION (0.25 mm) 14.4 (MAX. MEASURED AT HUB) 7.9 (MIN.) 10.9 (MAX.) Figure 12: Reeling Orientation User Feed Direction Cathode Side Printed Label Diameter ID should be bigger than 2.3 mm. 11

I v Bin Select (X 5 X 6 ) Individual reel will contain parts from 1 half bin only. Table 1: Minimum Intensity Bin Selection for HSMF-A201-xxxxx, HSMF-A204-xxxxx, HSMF-A206-xxxxx X 5 Color 1 (Red/ Yellow/Orange) Color 2 (Green) A K2 L1 B K2 L2 C K2 M1 D K2 M2 E K2 N1 F L1 L1 G L1 L2 H L1 M1 J L1 M2 K L1 N1 L L2 L1 M L2 L2 N L2 M1 P L2 M2 Q L2 N1 R M1 L1 S M1 L2 T M1 M1 U M1 M2 V M1 N1 W M2 L1 X M2 L2 Y M2 M1 Z M2 M2 1 M2 N1 Table 2: Minimum Intensity Bin Selection for HSMF-A202-xxxxx X 5 Color 1 (Red) Color 2 (Yellow) A K2 K1 B K2 K2 C K2 L1 D K2 L2 E K2 M1 F L1 K1 G L1 K2 H L1 L1 Table 2: Minimum Intensity Bin Selection for HSMF-A202-xxxxx (Continued) J L1 L2 K L1 M1 L L2 K1 M L2 K2 N L2 L1 P L2 L2 Q L2 M1 R M1 K1 S M1 K2 T M1 L1 U M1 L2 V M1 M1 W M2 K1 X M2 K2 Y M2 L1 Z M2 L2 1 M2 M1 X 5 Color 1 (Red) Color 2 (Yellow) Table 3: Minimum Intensity Bin Selection for HSMF- A203-xxxxx and HSMF-A205-xxxxx X 5 Color 1 (Red/ Orange) Color 2 (Green) A K2 J1 B K2 J2 C K2 K1 D K2 K2 E K2 L1 F L1 J1 G L1 J2 H L1 K1 J L1 K2 K L1 L1 L L2 J1 M L2 J2 N L2 K1 P L2 K2 Q L2 L1 R M1 J1 S M1 J2 T M1 K1 U M1 K2 12

Table 3: Minimum Intensity Bin Selection for HSMF- A203-xxxxx and HSMF-A205-xxxxx (Continued) X 5 V M1 L1 W M2 J1 X M2 J2 Y M2 K1 Z M2 K2 1 M2 L1 Table 4: Minimum Intensity Bin Selection for HSMF-A211-xxxxx X 5 Color 1 (Red) Color 2 (Green) A L2 L1 B L2 L2 C L2 M1 D L2 M2 E L2 N1 F M1 L1 G M1 L2 H M1 M1 J M1 M2 K M1 N1 L M2 L1 M M2 L2 N M2 M1 P M2 M2 Q M2 N1 R N1 L1 S N1 L2 T N1 M1 U N1 M2 V N1 N1 W N2 L1 X N2 L2 Y N2 M1 Z N2 M2 1 N2 N1 Color 1 (Red/ Orange) 0 represents full distribution. Color 2 (Green) Table 5: Minimum Intensity Bin Selection for HSMF-A212-xxxxx X 5 Color 1 (Red) Color 2 (Yellow) A L2 K1 B L2 K2 C L2 L1 D L2 L2 E L2 M1 F M1 K1 G M1 K2 H M1 L1 J M1 L2 K M1 M1 L M2 K1 M M2 K2 N M2 L1 P M2 L2 Q M2 M1 R N1 K1 S N1 K2 T N1 L1 U N1 L2 V N1 M1 W N2 K1 X N2 K2 Y N2 L1 Z N2 L2 1 N2 M1 Table 6: Minimum Intensity Bin Selection for HSMF-A222-xxxxx X 5 Color 1 (Red) Color 2 (Amber) A P1 P1 B P1 P2 C P1 Q1 D P1 Q2 E P1 R1 F P2 P1 G P2 P2 H P2 Q1 J P2 Q2 K P2 R1 L Q1 P1 13

Table 6: Minimum Intensity Bin Selection for HSMF-A222-xxxxx (Continued) X 5 Color 1 (Red) Color 2 (Amber) M Q1 P2 N Q1 Q1 P Q1 Q2 Q Q1 R1 R Q2 P1 S Q2 P2 T Q2 Q1 U Q2 Q2 V Q2 R1 W R1 P1 X R1 P2 Y R1 Q1 Z R1 Q2 1 R1 R1 2 R2 P1 3 R2 P2 4 R2 Q1 5 R2 Q2 6 R2 R1 Table 7: Minimum Intensity Bin Selection for HSMF-A341-xxxxx X 5 Color 1 (Red/ Red Orange) Color 2 (Green) Color 3 (Blue) A P1 R1 N1 B P1 R1 N2 C P1 R1 P1 D P1 R2 N1 E P1 R2 N2 F P1 R2 P1 G P1 S1 N1 H P1 S1 N2 J P1 S1 P1 K P2 R1 N1 L P2 R1 N2 M P2 R1 P1 N P2 R2 N1 P P2 R2 N2 Q P2 R2 P1 R P2 S1 N1 S P2 S1 N2 Table 7: Minimum Intensity Bin Selection for HSMF-A341-xxxxx (Continued) X 5 Color 1 (Red/ Red Orange) Color 2 (Green) T P2 S1 P1 U Q1 R1 N1 V Q1 R1 N2 W Q1 R1 P1 X Q1 R2 N1 Y Q1 R2 N2 Z Q1 R2 P1 1 Q1 S1 N1 2 Q1 S1 N2 3 Q1 S1 P1 4 Q2 R1 N1 5 Q2 R1 N2 6 Q2 R1 P1 7 Q2 R2 N1 8 Q2 R2 N2 9 Q2 R2 P1 Number of Half Bins from X 5 Table 8: Number of Half Bins from X5 for HSMF-A2xx-xxxxx X 6 Color 1 Color 2 0 0 0 A 0 5 B 0 4 C 0 3 D 0 2 E 5 0 F 5 5 G 5 4 H 5 3 J 5 2 K 4 0 L 4 5 M 4 4 N 4 3 P 4 2 Q 3 0 R 3 5 S 3 4 T 3 3 Color 3 (Blue) 14

Table 8: Number of Half Bins from X5 for HSMF-A2xx-xxxxx X 6 Color 1 Color 2 U 3 2 V 2 0 W 2 5 X 2 4 Y 2 3 Z 2 2 0 represents full distribution. Table 9: Number of Half Bins from X5 for HSMF-A3xx-xxxxx X 6 Color 1 (Red/ Red Orange) Color 2 (Green) Color 3 (Blue) 0 0 0 0 A 5 5 5 B 5 5 4 C 5 5 3 D 5 4 5 E 5 4 4 F 5 4 3 G 5 3 5 H 5 3 4 J 5 3 3 K 4 5 5 L 4 5 4 M 4 5 3 N 4 4 5 P 4 4 4 Q 4 4 3 R 4 3 5 S 4 3 4 T 4 3 3 U 3 5 5 V 3 5 4 W 3 5 3 X 3 4 5 Y 3 4 4 Z 3 4 3 1 3 3 5 2 3 3 4 3 3 3 3 0 represents full distribution. Intensity Bin Limits Tolerance of each bin limit = ±10%. Color Bin Select (X 7 ) Bin ID Min. (mcd) Max. (mcd) J1 4.50 5.60 J2 5.60 7.20 K1 7.20 9.00 K2 9.00 11.20 L1 11.20 14.00 L2 14.00 18.00 M1 18.00 22.40 M2 22.40 28.50 N1 28.50 35.50 N2 35.50 45.00 P1 45.00 56.00 P2 56.00 71.50 Q1 71.50 90.00 Q2 90.00 112.50 R1 112.50 140.00 R2 140.00 180.00 S1 180.00 224.00 S2 224.00 285.00 T1 285.00 355.00 T2 355.00 450.00 U1 450.00 560.00 U2 560.00 715.00 V1 715.00 900.00 V2 900.00 1125.00 Individual reel will contain parts from 1 full bin only. Table 10: Color Bin Select for HSMF-A202-xxxxx, HSMF-A203-xxxxx, HSMF-A212-xxxxx, HSMF-A222-xxxxx X 7 Color 1 (Red) Color 2 (Emerald Green/ Yellow/Blue) 0 0 0 A 0 ABC B 0 ABCD C 0 ABCDE D 0 BCD E 0 BCDE F 0 BCDEF 15

Table 10: Color Bin Select for HSMF-A202-xxxxx, HSMF-A203-xxxxx, HSMF-A212-xxxxx, HSMF-A222-xxxxx X 7 G 0 CDE H 0 DEF J 0 CDEF K 0 AB L 0 BC M 0 CD N 0 DE P 0 EF Color 1 (Red) 0 represents full distribution. Table 11: Color Bin Select for HSMF-A201-xxxxx and HSMF-A211-xxxxx X 7 Color 1 (Red) Color 2 (Yellow Green) 0 0 0 A 0 EFG B 0 FGH C 0 EF D 0 FG E 0 GH 0 represents full distribution. Color 2 (Emerald Green/ Yellow/Blue) Table 12: Color Bin Select for HSMF-A205-xxxxx X 7 Color 1 (Yellow/ Amber/Orange) Color 2 (Emerald Green/Blue) 0 0 0 A ABC ABC B BCD ABC C CDE ABC D ABC BCD E BCD BCD F CDE BCD G ABC CDE H BCD CDE J CDE CDE K DEF ABC L DEF BCD M DEF CDE N AB AB Table 12: Color Bin Select for HSMF-A205-xxxxx 0 represents full distribution. Color 1 (Yellow/ Color 2 (Emerald X 7 Amber/Orange) Green/Blue) P BC AB Q CD AB R DE AB S AB BC T BC BC U CD BC V DE BC W AB CD X BC CD Y CD CD Z DE CD 1 AB DE 2 BC DE 3 CD DE 4 DE DE 5 EF AB 6 EF BC 7 EF CD Table 13: Color Bin Select for HSMF-A204-xxxxx and HSMF-A206-xxxxx X 7 Color 1 (Yellow/ Amber/Orange) Color 2 (Yellow Green) 0 0 0 A ABC EFG B BCD EFG C CDE EFG D DEF EFG E ABC FGH F BCD FGH G CDE FGH H DEF FGH J AB EF K BC EF L CD EF M DE EF N EF EF P AB FG Q BC FG R CD FG 16

Table 13: Color Bin Select for HSMF-A204-xxxxx and HSMF-A206-xxxxx X 7 S DE FG T EF FG U AB GH V BC GH W CD GH X DE GH Y EF GH Color 1 (Yellow/ Amber/Orange) 0 represents full distribution. Color 2 (Yellow Green) Table 14: Color Bin Select for HSMF-A3xx-xxxxx X 7 Color 1 Color 2 Color 3 0 0 0 0 A 0 0 ABC B 0 0 BCD C 0 0 AB D 0 0 BC E 0 0 CD F 0 ABC 0 G 0 ABC ABC H 0 ABC BCD J 0 ABC AB K 0 ABC BC L 0 ABC CD M 0 BCD 0 N 0 BCD ABC P 0 BCD BCD Q 0 BCD AB R 0 BCD BC S 0 BCD CD T 0 AB ABC U 0 AB BCD V 0 AB AB W 0 AB BC X 0 AB CD Y 0 BC ABC Z 0 BC BCD 1 0 BC AB 2 0 BC BC 3 0 BC CD 4 0 CD ABC Table 14: Color Bin Select for HSMF-A3xx-xxxxx 5 0 CD BCD 6 0 CD AB 7 0 CD BC 8 0 CD CD 0 represents full distribution. Color Bin Limits Blue Min. (nm) Max. (nm) A 460.0 465.0 B 465.0 470.0 C 470.0 475.0 D 475.0 480.0 Green Min. (nm) Max. (nm) A 515.0 520.0 B 520.0 525.0 C 525.0 530.0 D 530.0 535.0 Emerald Green Min. (nm) Max. (nm) A 552.5 555.5 B 555.5 558.5 C 558.5 561.5 D 561.5 564.5 Yellow Green Min. (nm) Max. (nm) E 564.5 567.5 F 567.5 570.5 G 570.5 573.5 H 573.5 576.5 Amber/Yellow Min. (nm) Max. (nm) A 582.0 584.5 B 584.5 587.0 C 587.0 589.5 D 589.5 592.0 X 7 Color 1 Color 2 Color 3 17

Amber/Yellow Min. (nm) Max. (nm) E 592.0 594.5 F 594.5 597.0 Packaging Option (X 8 X 9 ) X 8 X 9 J1 20 ma test current, Top Mount, 7-inch Reel Orange Min. (nm) Max. (nm) A 597.0 600.0 B 600.0 603.0 C 603.0 606.0 D 606.0 609.0 E 609.0 612.0 Red Orange Min. (nm) Max. (nm) A 611.0 616.0 B 616.0 620.0 Red Min. (nm) Max. (nm) Full Distribution 18

Precautionary Notes Soldering Do not perform reflow soldering more than twice. observe necessary precautions of handling moisture-sensitive devices as stated in the following section. Do not apply any pressure or force on the LED during reflow and after reflow when the LED is still hot. Use reflow soldering to solder the LED. Use hand soldering only for rework if unavoidable, but it must be strictly controlled to following conditions: Soldering iron tip temperature = 315 C maximum. Soldering duration = 3 seconds maximum. Number of cycles = 1 only. Power of soldering iron = 50W maximum. Do not touch the LED package body with the soldering iron except for the soldering terminals, because it may cause damage to the LED. Confirm beforehand whether the functionality and performance of the LED is affected by soldering with hand soldering. Figure 13: Recommended Lead-Free Reflow Soldering Profile TEMPERATURE 217 C 200 C 150 C 255 260 C 3 C/SEC. MAX. 3 C/SEC. MAX. 10 to 30 SE 6 C/SEC. MAX. 60 120 SEC. 100 SEC. MAX. TIME Figure 14: Recommended Board Reflow Direction Handling Precautions Handling of Moisture-Sensitive Devices This product has a Moisture Sensitive Level 2a rating per JEDEC J-STD-020. Refer to Application Note AN5305, Handling of Moisture Sensitive Surface Mount Devices, for additional details and a review of proper handling procedures. Before use: An unopened moisture barrier bag (MBB) can be stored at <40 C/90% RH for 12 months. If the actual shelf life has exceeded 12 months and the Humidity Indicator Card (HIC) indicates that baking is not required, then it is safe to reflow the LEDs per the original MSL rating. Do not open the MBB prior to assembly (for example, for IQC). If unavoidable, the MBB must be properly resealed with fresh desiccant and the HIC. The exposed duration must be taken in as floor life. Control after opening the MBB: Read the HIC immediately upon opening of the MBB. Keep the LEDs at <30 /60% RH at all times, and complete all high temperature-related processes, including soldering, curing or rework within 672 hours. Control for unfinished reel: Store unused LEDs in a sealed MBB with desiccant or a desiccator at <5% RH. Control of assembled boards: If the PCB soldered with the LEDs is to be subjected to other high-temperature processes, store the PCB in a sealed MBB with desiccant or desiccator at <5% RH to ensure that all LEDs have not exceeded their floor life of 168 hours. Baking is required if: The HIC indicator indicates a change in color for 10% and 5%, as stated on the HIC. The LEDs are exposed to conditions of >30 C/60% RH at any time. The LED's floor life exceeded 672 hours. The recommended baking condition is: 60 C ± 5ºC for 20 hours. Baking can only be done once. 19

Storage: The soldering terminals of these LEDs are silver plated. If the LEDs are exposed in an ambient environment for too long, the silver plating might be oxidized, thus affecting its solderability performance. As such, keep unused LEDs in a sealed MBB with desiccant or in a desiccator at <5% RH. Application Precautions The drive current of the LED must not exceed the maximum allowable limit across temperature as stated in the data sheet. Constant current driving is recommended to ensure consistent performance. Circuit design must cater to the whole range of forward voltage (V F ) of the LEDs to ensure the intended drive current can always be achieved. The LED exhibits slightly different characteristics at different drive currents, which may result in a larger variation of performance (meaning: intensity, wavelength, and forward voltage). Set the application current as close as possible to the test current to minimize these variations. Do not use the LED in the vicinity of material with sulfur content or in environments of high gaseous sulfur compounds and corrosive elements. Examples of material that might contain sulfur are rubber gaskets, room- temperature vulcanizing (RTV) silicone rubber, rubber gloves, and so on. Prolonged exposure to such environments may affect the optical characteristics and product life. White LEDs must not be exposed to acidic environments and must not be used in the vicinity of any compound that may have acidic outgas, such as, but not limited to, acrylate adhesive. These environments have an adverse effect on LED performance. Avoid rapid change in ambient temperature, especially in high-humidity environments, because they cause condensation on the LED. If the LED is intended to be used in harsh or outdoor environment, protect the LED against damages caused by rain water, water, dust, oil, corrosive gases, external mechanical stresses, and so on. Thermal Management Optical, electrical, and reliability characteristics of LED are affected by temperature. The junction temperature (T J ) of the LED must be kept below allowable limit at all times. T J can be calculated as follows: T J = T A + R θj-a I F V Fmax where: T A = Ambient temperature ( C) R θj-a = Thermal resistance from LED junction to ambient ( C/W) I F = Forward current (A) V Fmax = Maximum forward voltage (V) The complication of using this formula lies in T A and R θj-a. Actual T A is sometimes subjective and hard to determine. R θj-a varies from system to system depending on design and is usually not known. Another way of calculating T J is by using solder point temperature T S as follows: T J = T S + R θj-s I F V Fmax where: T S = LED solder point temperature as shown in the following figure ( C) R θj-s = Thermal resistance from junction to solder point ( C/W) T S can be easily measured by mounting a thermocouple on the soldering joint as shown in preceding figure, while R θj-s is provided in the data sheet. Verify the T S of the LED in the final product to ensure that the LEDs are operating within all maximum ratings stated in the data sheet. 20

Eye Safety Precautions LEDs may pose optical hazards when in operation. Do not look directly at operating LEDs because it might be harmful to the eyes. For safety reasons, use appropriate shielding or personal protective equipment. 21

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